Scientists collaborating on the mission also say the rock samples, which the rover has cached in tubes for a future return to Earth, have the right chemical recipe to preserve evidence of ancient Martian life, if it ever existed.
The new Perseverance research is detailed in three extensive studies published Wednesday, one in the journal Science and two in the journal Science Advances. The journal reports are highly technical and devoid of hype — daring to be dull as dirt — but the scientists involved translate them into a more exciting tale.
“It’s amazing. In pretty much every rock we’re finding organics,” said Abigail Allwood, a geologist at the NASA Jet Propulsion Laboratory in Pasadena, which operates the rover and the broader Mars Sample Return mission.
One of the studies concluded that the rocks in the crater experienced three different events in which they were exposed to water.
“Crucially, conditions in the rock during each time that water migrated through it could have supported small communities of microorganisms,” lead author Michael Tice, a geologist at Texas A&M University, said in an email. In a subsequent interview, he added, “We’re not going to know until we get the samples back to Earth.”
Perseverance made a bulls-eye landing in Jezero Crater on Feb. 18, 2021, and has been roaming it since, caching rock samples along the way for later scrutiny back on Earth. This is an ambitious, multiphase mission that will require NASA and its partner, the European Space Agency, to send another vehicle to the surface of Mars with the capability of launching samples into orbit. A spacecraft would then carry those samples back to Earth for laboratory research. The precise timetable is yet to be determined, but NASA is hoping to have the samples on home turf in the early 2030s.
This study of Mars is part of the efflorescence of the young field of astrobiology, which includes the search for potentially habitable worlds and the first example of extraterrestrial life. Despite the efforts of generations of scientists, and notwithstanding the claims of UFO buffs, the discovery of life beyond Earth remains aspirational.
Even finding organics — life-friendly molecules with combinations of carbon, hydrogen and oxygen — is a far cry from discovering life or even proof of its presence in the past. Such molecules can be either biological or nonbiological in origin.
Still, Mars is front and center in NASA’s search because it has many favorable traits. Mars was probably far more Earthlike about 3 billion years ago, with warmer and wetter conditions. Life may have once existed on Earth and Mars simultaneously, and it is possible that it originated on Mars and spread to Earth via meteorites. And though the surface now is an arid wasteland, the planet could have liquid water in significant quantities beneath the surface, and possibly “cryptic” life.
Although the Perseverance rover does not have instruments to chemically detect living organisms if they exist today, its instruments give scientists the ability to study the Martian surface at a level of detail never before possible.
One of the new papers more closely examining Mars’s chemistry has delivered a surprise for geologists. They had assumed that they were going to dig up a bunch of sedimentary rocks. Instead the rocks are volcanic.
Jezero Crater formed in an impact event — a rock slamming into Mars — at least 3.5 billion years ago. The shallow crater clearly had water in it long ago. This could be determined from orbital images showing the remnants of a delta where a river flowed into the lake. Planetary geologists had assumed the floor of the crater was covered in sedimentary rock, formed from dirt and debris that slowly accumulated at the bottom of the lake.
If such sedimentary rock was ever there, it’s gone now. It may have eroded away, Tice said. The lack of sedimentary rock could mean that the lake didn’t last very long, which would be disappointing for astrobiologists. Life as we know it needs water, and it takes time for more-complex life-forms to evolve. If the lake didn’t linger, life might have struggled to take root.
The volcanic rocks are not a disappointment, though, because they preserve loads of information about the Martian past, including the presence of organic molecules, scientists said. The presence of organic material on Mars had been confirmed in previous missions, but their precise nature and chemistry can’t be discerned through this kind of long-distance research and will require laboratory scrutiny on Earth, according to Bethany Ehlmann, a planetary scientist at Caltech and co-author of two of the new papers.
“Are they merely organics that kind of washed into the system — maybe from meteoritic material that was just part of the water? That would be the least exciting. Or are they little niches of microbial life living in the cavities of these rocks? That would be the most exciting,” Ehlmann said.
She added that the rover “is collecting an awesome set of samples to reveal Mars’s environmental history in all of its forms — the volcanic history, the history of water, the relationship of organics to those water-rich environments.”
All of this is an attempt to solve the fundamental mystery of Mars: What went wrong? How and when and why did this planet that apparently was congenial to life turn into such a harsh place? The Red Planet may not be a dead planet — the coroner’s report is incomplete — but it certainly resembles one.
Scientists point to something Mars lacks today: a global magnetic field like Earth’s. Such a field protects our atmosphere from the corrosive effects of the solar wind — high-energy particles steadily streaming from the sun that can strip away lighter molecules. Mars also lacks plate tectonics, the geological process that on Earth recycles the crust and continues to spew water and nutrient-rich lavas through active volcanoes.
Somewhere along the way, Mars’s magnetic field died, and then it became a different kind of planet. It lost almost all of its atmosphere. It became a frigid desert world. How quickly that happened is unknown, but that’s something that might be revealed by the volcanic rocks in the crater.
Magma contains some amount of iron, which is sensitive to a planet’s magnetism. As lava cools, it crystallizes into igneous rock, freezing electrons within iron-bearing minerals into patterns that could reveal a magnetic field’s traits, such as its orientation.
Benjamin Weiss, a planetary scientist at MIT and co-author of two of the papers, said in an email, “On balance, we are actually super lucky that there are igneous rocks in the crater, and that we happened to land right on them , since they are ideal for determining ages and studying the past history of Mars’ magnetic field.”
Once the mission can send its precious rock collection back to Earth, scientists may finally be able to tell if life ever found a foothold on Mars — which would raise new questions about whether, despite the dramatic transformation of the planet, life somehow managed to persevere .